DE1167927B - Transmitter protection circuit - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Boarding school Class: H 04 b

Number:
File number:
Registration date:
Display day:

German class: 21 a4 - 76

S 79180 IXd / 21 a4
April 26, 1962
April 16, 1964

The operation of transmitters, especially high-power transmitters, requires constant monitoring the operating behavior a number of facilities and measures. Processes deviating from normal operating behavior, such as B. Tube flashovers or mismatches between the transmitter output and the antenna must be displayed immediately or be parked independently as soon as possible.

To z. B. to protect a transmitter tube from destruction in the event of a tube flashover, it is necessary to Immediately switch off the anode and screen grid voltage of the tube in order to generate the to extinguish the resulting arc. To do this, the transmission operation only needs to be interrupted for a short time will. After a period of about 0.1 to 0.5 seconds, the voltages that have been switched off can be reapplied will. Repeats in a period of e.g. B. 1 minute the tube flashover several times, an additional measure is then required to ensure that the Anode and screen grid voltage is prevented.

It is known to have such or similar protective circuits in transmission systems, as in the example mentioned a reclosing device, a counting device and a blocking device, by means of relay circuits to realize. These protective circuits are also used to temporarily switch off the operating voltages used in case of transmitter mismatch.

Apart from the large amount of relays, contactors and switches involved in manufacturing of protective circuits of several interlocking functions is required, arises in Depending on the number of electrical contacts, a growing degree of operational uncertainty, the especially due to external influences such as moisture, pollution, chemical changes to the contact surfaces is conditional.

The invention is based on the object for the function of a reclosing, counting and blocking to monitor tube flashovers or occurring mismatches Specify circuit by which the disadvantages of known relay circuits are avoided. According to of the invention this is achieved by a transmitter protection circuit in which, using Active and passive assemblies with contactless, controlled by 'signals (control signal, zero signal) Components, e.g. B. transistors, diodes, the short-term initiated by a signal change Interruption of the anode and screen grid chip transmitter protection circuit

Applicant:

Siemens & Halske Aktiengesellschaft,

Berlin and Munich,

Munich 2, Wittelsbacherplatz 2

Named as inventor:
Dipl.-Ing. Rüdiger Schünemann,
Berlin-Halensee

tion via a signal reversing stage, the output signal of which in a time tipping stage sets the interruption time determining control signal adjustable

so duration is generated, and via a further inversion stage, the output of which leads to a zero signal during the interruption time, is triggered, and that for blocking of the operating voltages the control signal received at the output of the time tipper stage after signal reversal controls a binary level in an inversion level through the signal change (control signal / zero signal) and at their two outputs carrying different signals (control signal, zero signal) Signal reversal causes, and that one of the outputs (or alternately one of the two outputs) on one of the inputs of one (or more) step counter is performed and the control signal is leading Output via a switch for setting the number of permissible control pulses, e.g. B. Tube flashovers, optionally directly via a memory storing the control signal with a die Disabling triggering power stage and a second input of the interruption triggering Reversing stage and a time tipping stage for pulse stretching that determines the duration of the counting process and connected to a subsequent delay addition to a second input of the first counter stage whose output is a control signal when inputs are simultaneously acted upon by a control signal the input of a further counting stage and via the switch to the input of the memory.

The invention is explained in more detail using an exemplary embodiment. In the

F i g. 1 the anode power supply of two transmitter tubes is indicated in principle; in the

Fig. 2 shows a block diagram of the whole Protection circuit while in

409 599/399

F i g. 3 shows a block diagram of the reclosing, counting and blocking device; the

F i g. 4 a to 4 g show the circuits of the assemblies used in detail.

The transmitter is supplied with power from the three-phase network R, S, T, which is connected to the rectifier arrangements Gl and G 2 connected in parallel via the contacts sch of a contactor. In terms of direct current, only the electrical connections for the anode voltage are indicated. In the cathode line of the tubes and R oil ROE2 the overcurrent relay UEL and T 2 are disposed, which are connected in series above the contacts 1 and u 2 (Fig. 2) are assigned. In the event of a tube flashover in one of the two tubes, the associated relay Ül or Ü2 is excited by the overcurrent and one of the contacts Ül, Ü2 is opened.

All details of the transmitter circuit which do not serve to explain the invention are shown in FIG. 1 not shown. Screen grid tubes can also be used in place of the triodes / oil and tube 2. The individual functions of the protective circuit (restarting, counting and blocking) are triggered by tube flashovers or, in the event of a mismatch of the transmitter, via the detuning protection, which result in a short-term or permanent interruption of the power supply by means of the contactor Sch .

The protective circuit essentially consists of the restart, counting and blocking device WE with the power supply part V and several auxiliary devices for switching off the operating voltages. The power supply part V supplies at its output terminals N, MP and P the operating voltages required for the entire control device, which in the form of signals cause all switching elements to be modulated. The output P carries a positive voltage of z. B. +24 V to the output MP, whose ground potential is referred to as the zero signal. The output N leads to the output MP a negative voltage of z. B. - 24 V, which is referred to below as the control signal.

The input and output terminals of the reclosing, counting and blocking device WE are denoted by the numbers 1 to 8 and the letters a, b, c . Terminal 3, which is connected to the output N of the power supply V via the normally closed contacts ü 1, Ü2 of the overcurrent relays Ül and Ü2 , is to be regarded as the main input. As long as contacts ül and ü 2 are closed, terminal 3 carries a control signal. Terminals 4 and 7 are used to switch on the anode and screen grid voltage or to block them.

To switch on the anode and screen grid voltage of the transmitter tubes, after the power supply V has been switched on, the main switch T must be operated, which applies the control signal to terminal 8. When the power supply is switched on, the "And" gate X1 and X2 control signal appears at terminals 4 and 7 and thus at one input each. The second input of each of the “And” gates already receives a control signal when the switch T is closed. Since both inputs of the “And” gate X 2 receive control signal, the output of the “And” gate X2 also carries the control signal that the power stage P 2 modulates. The earthing switch £ located in the collector circuit of power stage P 2 is energized and the short circuit required for rapid discharge of the sieve chains is eliminated. Via contact e , the control signal is brought to the third input of the “And” gate Xl, which brings the contactor Sch to pull in. The contacts sch (Fig. 1) of the contactor are closed. The anode and screen grid voltage are then switched on.
In the event of a tube flashover, one of the contacts ül or ü2 is opened. A zero signal appears immediately at terminal 4 and thus at power level P 1 for a short adjustable period of time from 0.1 to 0.5 seconds. The contactor Sch opens its contacts for this time and switches off the operating voltage. After the brief interruption, the previous status is restored.

Is required that within a period of 1 minute z. If, for example, no more than six tube flashovers are to be allowed, then in connection with the restart, counting and blocking device at the sixth tube flashover, a zero signal is also sent to terminals 6 and 7 and thus to power level P 2. This causes the contactors Sch and E from. The restart of the operating voltage is now blocked as long as the main switch T is not opened and then closed again.

A control lamp L can be connected to the terminal 6 of the reclosing, counting and locking device, lighting up at blocking.

Control signal pulses from another protective device, e.g. B. Detuning protection, can be entered, which also disables the operating voltages after a specified number of times trigger.

A counter Z can be connected to terminal 2 via a power stage P 3, with which all interruptions in the overcurrent loop are counted.

If a control signal is given to terminal 5 via a test button PT , the function of all stages can be checked, since all stages except for stage Nl, NIl (FIG. 3) work exactly like a tube flashover.

The reclosing, counting and locking device WE (Fig. 3) consists of a number of logic operations subject assemblies with contactless components such as transistors, diodes, which are controlled by signals (control signal, zero signal). The entire control process is based on a combination of logical, time-independent and time-dependent basic functions that are carried out by the assemblies indicated in the block diagram.

The assemblies combined in the circuit ( FIG. 3) - reversing stages N, kipper K, binary stage B, counting step 51 to S 5, delay additive TK, memory M and power stage P - are shown with circuit details in FIGS. 4a to 4g.

How the functions of the control circuit are implemented will be shown below using these circuit diagrams.
The F i g. 4 a shows an inversion stage N as an assembly combined with an “OR” gate. The inverse function requests the inverse input signal at output ^ ο. The output, 4 ο or Al should therefore carry a control signal if both inputs

gen 11, 12 or 01, 02 zero signal is pending, and it has a zero signal when a control signal is pending at one of the inputs. When the transistor of this circuit is blocked, the output Ao or A 1 is at potential (N) across the resistor; the output thus carries a control signal (-24V). If, on the other hand, there is a control signal at one of the three inputs, a control current flows through the emitter-base path, the transistor becomes permeable and the collector assumes the potential MP, ie a zero signal appears at the output.

The Kipper .K (time stage, Fig. 4b) is based on a time function. The timer should only maintain a signal for a very specific adjustable time. A monostable tipper with i? C external wiring is used for this purpose. With a zero signal at the inputs 11, 12 and 13, the transistor ti is permeable; namely he gets his control current through the resistor R. The output Al therefore has zero signal. The coupling of the base of the transistor ti to the collector of the transistor

10 happens through a capacitor C, which is initially uncharged. With a control signal at one of the inputs 11, 12 or 13, the transistor becomes permeable. The collector receives the potential MP. The potential at point 32 is strongly positive with respect to MP due to the charge of the capacitor and immediately blocks transistor ti. At the output Al therefore control signal appears. The capacitor C is now recharged according to the voltage across the resistor r0 via the resistor R and lets the potential at point 32 wander in the negative direction. If this potential is sufficiently negative, the transistor ti becomes permeable again. The control signal at output A1 disappears. The duration of the control signal at output A1 is determined by the capacitance of the capacitor C and the size of the resistor R and can be selected between fractions of a second and several seconds.

Another form of the time stage is the additional delay TK (FIG. 4c), which, in conjunction with the tipper K, causes an adjustable signal delay. When the time tipper K is interconnected with the delay additive TK , a control signal pending at one of the inputs 11 or 12 of the tipper causes a control signal to be present at the output A1 of the delay additive for a time defined with the i? C combination of the tipper K. With the disappearance of the control signal at the output of Al a momentary control signal arrives at the output of A2.

The mode of operation of the binary stage B (FIG. 4d) is such that the signals at the outputs A1 and A o are reversed (control signal becomes zero signal, zero signal becomes control signal) when there is a change from control signal to zero signal at its input 22. Control signal at one of the inputs 01 or 02 causes a control signal at output Ao.

The counting step S (Fig. 4e) is a counting stage that consists of an “AND” gate and an active module. If there is a control signal at both inputs 01 and 02, output Ao carries a control signal, even if the input signal disappears again. Will control signal on the input

11 given, a zero signal appears at output Ao.

The memory M (Fig. 4f) performs the function of a memory. When the power supply is switched on, suitable switching means force the transistor ti to pass and the transistor to be blocked. The prerequisite is that there is no control signal at input 11. This state is self-sustaining, as there is a control signal at output Ao and control current for transistor ti is supplied via the "Or" input. Conversely, the zero signal at A1 keeps transistor t0 blocked. If a control signal now appears at input 11, the transistor is OK and the voltage at output Ao collapses. The control current of the transistor ti disappears and the output A1 receives a control signal. This state remains stable, even if the input signal at input 11 disappears, and can only be deleted by a control signal at one of the inputs 01 or 02.

The power levels P (Fig. 4g) have the task of changing from the command processing part to the actuating elements, z. B. contactor to effect necessary power amplification and consist of multi-stage transistor amplifiers. If a control signal is sent to input 11 of a power stage, output ^ ο carries a zero signal.

The mode of operation of the entire circuit for reclosing, counting and blocking is illustrated in FIG. 3 described. When the power supply V (FIG. 2) is switched on, a control signal is applied to input 02 of binary level B and to inputs 01 of memory Ml and M 2 via iV2II. The initial state is thus established. The binary stage B has a control signal at output A ο and the step counter Sl to SS at outputs Ao a zero signal.

The anode and screen grid voltage of the transmitter tubes Röl and Rö2 are switched on via the main switch T (FIG. 2), which applies the control signal to terminal 8 of the inverter N 2 II so that a zero signal appears at its output A1. This control signal is applied to one input each of the "And" gridset Xl and X 2 Speaking now as a result of an overcurrent in one of the transmitter tube, the relay UEL or Ü2 to, the associated break contact is til or above 2 opened so that the entrance 3 the inverter N II the control signal disappears. At the same time appears at the output Ao of this reversing stage and thus also at the input 12 of the time kipper .O control signal. At the output Al of the stage Kl and at the inputs 11 of the inverting stage N2 1 and 02 of the inverting stage NlII stands for a time dependent on the time constant C1, Wl , which by means of the variable resistor Wl z. B. adjustable between 0.1 and 0.5 seconds, control signal. This control signal causes a zero signal at the output A1 of the inverter TVIII and thus at terminal 4. As a result, the “And” condition of the “And” gate Xl is no longer met, the contactor Sch (Fig. 2) drops out and switches off the anode and screen grid voltages of the transmitter tubes on the primary side. At the same time the truck Kl generating a zero signal at the output of the invertor N 2 1 by the control signal at the output of Al. This results in a signal reversal at outputs A 1 and Ao of binary level B , ie output A 1 carries a control signal, output A ο a zero signal. The output A1 is connected to the input 11 of the memory M 2 , so that a control signal is also present here. Thereby also the output A 1 is the delay additive for the TK by the RC

Member Wl, Cl specified time a control signal of z. B. 60 sec., Which is led to the input 02 of the counter 51.

The addressed overcurrent relay drops after the mains voltage has been switched off by the contactor Sch after z. B. about 40 ms. After the time between 100 to 500 ms set with the resistor Wl of the time tipper stage Kl , a zero signal appears again at the output A 1 of this time tipper, so that the output A 1 (terminal 4) again carries a control signal and the contactor Sch switches on the anode and screen grid voltage again. The initial state has thus been reached again.

If another tube flashover occurs within 60 seconds, the individual stages work in the manner described above. At the second pulse, which is caused by a tube flashover, the binary level B again reverses the signal at the outputs, ie output Ao receives a control signal and output A 1 a zero signal. The control signal of the output Ao is also available at the input 01 of the counting stage 51. Since both inputs of the counting stage 51 now carry a control signal, a control signal also appears at the output Ao of this stage, and the first counting cut is done. In the event of further interruptions in the overcurrent loop, the outputs of the counting stages 52, 53, 54 or 55 then carry control signals one after the other.

Depending on the position of switch 5, either the control signal after the first tube flashover at output A 1 of binary level B or after further tube flashovers at one of the outputs of counting steps 51 to 55 is sent to input 11 of memory M1 . This means that there is also a control signal at output A1 of the memory, which does not disappear even after the rollover has been switched off. The control signal at the output of the memory generates a zero signal at output A o (terminals 6, 7) of the power stage P and at output A1 of the inverting stage iVHI (terminal 4), which are connected downstream of the memory. The shooters Sch and E drop out at the same time. The blocking that occurs as a result can only be canceled again when the control signal at terminal 8 is switched off by opening the main switch T. The output of the inverter Al N 2 II then performs control signal that both a resetting of the memories Ml and Ml effected via the inputs 01 as well as a deletion of the counts 51 to 55 on their inputs. 11 Only then can the anode and screen grid voltage be switched on again by closing the main switch T.

Transmitter protection circuits of the type described can advantageously be used under the trademark Maintenance-free switching units known from “Simatic” can be built, which are characterized by high operational reliability and short switching times.

60

Claims (12)

Patent claims: 1. Transmitter protection circuit, in particular for the brief interruption of the anode and screen grid voltage of one or more tubes after a tube flashover and / or to block these operating voltages after an adjustable number of tube flashovers that trigger control pulses or from control pulses from another protective device, e.g. B. detuning protection, characterized in that using active and passive assemblies with contactless, controlled by signals (control signal, zero signal) components such. B. transistors, diodes, the brief interruption of the anode and screen grid voltage initiated by a signal change via a signal reversing stage (NIl), the output signal of which in a time tipping stage (Kl) generates a control signal of adjustable duration that determines the interruption time, and via a further reversing stage (N III ), the output of which carries a zero signal during the interruption time, is triggered, and that the control signal received at the output of the time tipping stage (K 1) after signal reversal in an inverting stage (NlI) through the signal change (control signal, zero signal) is a binary stage (B ) and causes signal reversal at its two outputs carrying different signals (control signal, zero signal), and that one of the outputs (or alternately one of the two outputs) is led to one of the inputs of one (or more) step counters (51 to 55) , and the output carrying the control signal via a switch (5) for setting ung the number of permissible control pulses, e.g. B. tube flashovers, optionally directly via a memory (Ml) that stores the control signal with a power stage (P) that triggers the blocking and a second input of the reverse stage that triggers the interruption (iV III) and a time tipper stage (Kl) that determines the duration of the counting process Pulse stretching and the downstream delay additive (TK) is connected to a second input of the first counting stage (51), the output of which, when the inputs are simultaneously acted upon by a control signal, sends a control signal to the input of a further counting stage (52) and via the switch (5) to the input of the Memory (Ml) there. 2. Transmitter protection circuit according to claim 1, characterized in that upon termination of the signal expansion caused by the tipper stage (Kl) at a second output of the delay additive (TK) , a control signal is briefly formed which clears the counting steps of the counting stages (51 to 55) and the Binary level (B) resets to the initial state. 3. Transmitter protection circuit according to claim 1, characterized in that when the power supply to the assemblies of the protective device is switched on via an inverting stage (N 2 II), the output state of the binary stage (B) and the counting stages (51 to 55) is produced by a control signal. 4. Transmitter protection circuit according to claim 1, characterized in that after blocking the anode and screen grid voltage by opening the main switch (T) a signal reversing stage (NlU) a control signal to reset the memories (Ml, M2) and to delete the counting steps of the counting stages (51 up to 55). 5. transmitter protection circuit according to claim 1, characterized in that the by a Control signal of the reversing stage (NlII) triggered brief interruption of the operating voltages and the blocking of the operating voltages triggered by a control signal of the power stage (P) takes place via separate circuits. 6. Transmitter protection circuit according to claim 1 and 5, characterized in that the triggering of the circuits for the brief interruption and the blocking of the operating voltages takes place via an "and" gate (AT \, X7) . 7. Transmitter protection circuit according to claim 1, characterized in that the counting stages (51 up to 55) in addition to evaluating control pulses from another protective device, e.g. B. Detuning protection, can be used. 8. Transmitter protection circuit according to claim 7, characterized in that control pulses from other protective devices are given to the input of the inverter (N 21). 9. transmitter protection circuit according to claim 1, characterized in that the output of the Inverse stage (NlI) via a power stage with connected to a register. 10. Transmitter protection circuit according to claim 1, characterized in that the tipper stage (Kl) can be acted upon by a control signal via an additional input and a test button. 11. Transmitter protection circuit according to claim 1, characterized in that at the output A control lamp indicating the disabling of the operating voltages is connected to the power stage (P) is. 12. Transmitter protection circuit according to one of the preceding claims, characterized in that that switching units known under the trademark »Simatic« as with contactless Components populated active or passive assemblies are used. For this purpose 2 sheets of drawings 409 559/399 4.64 © Bundesdruckerei Berlin